#include "TEveCalo3DGL.h"
#include "TEveCalo.h"
#include "TMath.h"
#include "TAxis.h"
#include "TGLRnrCtx.h"
#include "TGLSelectRecord.h"
#include "TGLPhysicalShape.h"
#include "TGLIncludes.h"
#include "TGLUtil.h"
#include "TEveRGBAPalette.h"
#include "TEveUtil.h"
ClassImp(TEveCalo3DGL);
TEveCalo3DGL::TEveCalo3DGL() :
TGLObject(), fM(0)
{
fMultiColor = kTRUE;
}
Bool_t TEveCalo3DGL::SetModel(TObject* obj, const Option_t* )
{
fM = SetModelDynCast<TEveCalo3D>(obj);
return kTRUE;
}
void TEveCalo3DGL::SetBBox()
{
SetAxisAlignedBBox(((TEveCalo3D*)fExternalObj)->AssertBBox());
}
Bool_t TEveCalo3DGL::ShouldDLCache(const TGLRnrCtx& rnrCtx) const
{
if (rnrCtx.Highlight() || rnrCtx.Selection()) return kFALSE;
return TGLObject::ShouldDLCache(rnrCtx);
}
inline void TEveCalo3DGL::CrossProduct(const Float_t a[3], const Float_t b[3],
const Float_t c[3], Float_t out[3]) const
{
const Float_t v1[3] = { a[0] - c[0], a[1] - c[1], a[2] - c[2] };
const Float_t v2[3] = { b[0] - c[0], b[1] - c[1], b[2] - c[2] };
out[0] = v1[1] * v2[2] - v1[2] * v2[1];
out[1] = v1[2] * v2[0] - v1[0] * v2[2];
out[2] = v1[0] * v2[1] - v1[1] * v2[0];
}
void TEveCalo3DGL::RenderGridEndCap() const
{
using namespace TMath;
Float_t rB = fM->GetBarrelRadius();
Double_t zE = fM->GetEndCapPos();
Float_t etaMin = fM->GetEtaMin();
Float_t etaMax = fM->GetEtaMax();
Float_t trans = fM->GetTransitionEta();
Float_t phiMin = fM->GetPhiMin();
Float_t phiMax = fM->GetPhiMax();
TAxis *ax = fM->GetData()->GetEtaBins();
Int_t nx = ax->GetNbins();
TAxis *ay = fM->GetData()->GetPhiBins();
Int_t ny = ay->GetNbins();
Float_t r, z, theta, phiU, phiL, eta;
for (Int_t i=0; i<=nx; ++i)
{
eta = ax->GetBinUpEdge(i);
if (Abs(eta) >= trans && (eta > etaMin && eta < etaMax))
{
theta = TEveCaloData::EtaToTheta(eta);
r = Abs(zE*Tan(theta));
z = Sign(zE, ax->GetBinLowEdge(i));
for (Int_t j=1; j<=ny; ++j)
{
phiL = ay->GetBinLowEdge(j);
phiU = ay->GetBinUpEdge(j);
if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
{
glVertex3f(r*Cos(phiL), r*Sin(phiL), z);
glVertex3f(r*Cos(phiU), r*Sin(phiU), z);
}
}
}
}
Float_t r1, r2;
if (etaMax > trans)
{
r1 = zE*Tan(TEveCaloData::EtaToTheta(etaMax));
if (etaMin < trans)
r2 = rB;
else
r2 = zE*Tan(TEveCaloData::EtaToTheta(etaMin));
for (Int_t j=1; j<=ny; ++j)
{
phiL = ay->GetBinLowEdge(j);
phiU = ay->GetBinUpEdge(j);
if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
{
glVertex3f( r1*Cos(phiU), r1*Sin(phiU), zE);
glVertex3f( r2*Cos(phiU), r2*Sin(phiU), zE);
glVertex3f( r1*Cos(phiL), r1*Sin(phiL), zE);
glVertex3f( r2*Cos(phiL), r2*Sin(phiL), zE);
}
}
}
if (etaMin < -trans)
{
r1 = zE*Tan(TEveCaloData::EtaToTheta(etaMin));
if (etaMax > -trans)
r2 = rB;
else
r2 = zE*Tan(TEveCaloData::EtaToTheta(etaMax));
r1 = Abs(r1);
r2 = Abs(r2);
for (Int_t j=1; j<=ny; ++j)
{
phiL = ay->GetBinLowEdge(j);
phiU = ay->GetBinUpEdge(j);
if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
{
glVertex3f(r1*Cos(phiU), r1*Sin(phiU), -zE);
glVertex3f(r2*Cos(phiU), r2*Sin(phiU), -zE);
glVertex3f(r1*Cos(phiL), r1*Sin(phiL), -zE);
glVertex3f(r2*Cos(phiL), r2*Sin(phiL), -zE);
}
}
}
}
void TEveCalo3DGL::RenderGridBarrel() const
{
using namespace TMath;
Float_t etaMin = fM->GetEtaMin();
Float_t etaMax = fM->GetEtaMax();
Float_t trans = fM->GetTransitionEta();
Float_t phiMin = fM->GetPhiMin();
Float_t phiMax = fM->GetPhiMax();
Float_t rB = fM->GetBarrelRadius();
TAxis *ax = fM->GetData()->GetEtaBins();
Int_t nx = ax->GetNbins();
TAxis *ay = fM->GetData()->GetPhiBins();
Int_t ny = ay->GetNbins();
Float_t z, theta, phiL, phiU, eta, x, y;
for(Int_t i=0; i<=nx; i++)
{
eta = ax->GetBinUpEdge(i);
if ((Abs(eta)<=trans) && (etaMin < eta && eta < etaMax))
{
theta = TEveCaloData::EtaToTheta(eta);
z = rB/Tan(theta);
for (Int_t j=1; j<=ny; j++)
{
phiU = ay->GetBinUpEdge(j);
phiL = ay->GetBinLowEdge(j);
if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
{
glVertex3f(rB*Cos(phiL), rB*Sin(phiL), z);
glVertex3f(rB*Cos(phiU), rB*Sin(phiU), z);
}
}
}
}
Float_t zF, zB;
if (etaMin > -trans)
zB = rB/Tan(TEveCaloData::EtaToTheta(etaMin));
else
zB = -fM->GetEndCapPos();
if (etaMax < trans)
zF = rB/Tan(TEveCaloData::EtaToTheta(etaMax));
else
zF = fM->GetEndCapPos();
for (Int_t j=1; j<=ny; j++)
{
phiU = ay->GetBinUpEdge(j);
phiL = ay->GetBinLowEdge(j);
if (TEveUtil::IsU1IntervalContainedByMinMax(phiMin, phiMax, phiL, phiU))
{
x = rB * Cos(phiL);
y = rB * Sin(phiL);
glVertex3f(x, y, zB);
glVertex3f(x, y, zF);
x = rB * Cos(phiU);
y = rB * Sin(phiU);
glVertex3f(x, y, zB);
glVertex3f(x, y, zF);
}
}
}
void TEveCalo3DGL::RenderGrid(TGLRnrCtx & rnrCtx) const
{
if (rnrCtx.Highlight() || rnrCtx.Selection() || rnrCtx.IsDrawPassOutlineLine()) return;
Bool_t transparent_p = fM->fFrameTransparency > 0;
if (transparent_p)
{
glPushAttrib(GL_ENABLE_BIT | GL_DEPTH_BUFFER_BIT);
glDepthMask(GL_FALSE);
glEnable(GL_BLEND);
glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
TGLUtil::ColorTransparency(fM->fFrameColor, fM->fFrameTransparency);
}
TGLCapabilitySwitch lights_off(GL_LIGHTING, kFALSE);
TGLUtil::LineWidth(fM->GetFrameWidth());
glBegin(GL_LINES);
Float_t etaMin = fM->GetEtaMin();
Float_t etaMax = fM->GetEtaMax();
Float_t trans = fM->GetTransitionEta();
if (fM->GetRnrBarrelFrame() && (etaMin < trans && etaMax > -trans))
{
RenderGridBarrel();
}
if (fM->GetRnrEndCapFrame() && (etaMax > trans || etaMin < -trans))
{
RenderGridEndCap();
}
glEnd();
if (transparent_p)
{
glPopAttrib();
}
}
void TEveCalo3DGL::RenderBox(const Float_t pnts[8]) const
{
const Float_t *p = pnts;
Float_t cross[3];
glBegin(GL_POLYGON);
CrossProduct(p+3, p+9, p, cross);
glNormal3fv(cross);
glVertex3fv(p);
glVertex3fv(p+3);
glVertex3fv(p+6);
glVertex3fv(p+9);
glEnd();
glBegin(GL_POLYGON);
CrossProduct(p+21, p+15, p+12, cross);
glNormal3fv(cross);
glVertex3fv(p+21);
glVertex3fv(p+18);
glVertex3fv(p+15);
glVertex3fv(p+12);
glEnd();
glBegin(GL_POLYGON);
CrossProduct(p+12, p+3, p, cross);
glNormal3fv(cross);
glVertex3fv(p);
glVertex3fv(p+12);
glVertex3fv(p+15);
glVertex3fv(p+3);
glEnd();
glBegin(GL_POLYGON);
CrossProduct(p+6, p+21, p+9, cross);
glNormal3fv(cross);
glVertex3fv(p+9);
glVertex3fv(p+6);
glVertex3fv(p+18);
glVertex3fv(p+21);
glEnd();
glBegin(GL_POLYGON);
CrossProduct(p+21, p, p+9, cross);
glNormal3fv(cross);
glVertex3fv(p);
glVertex3fv(p+9);
glVertex3fv(p+21);
glVertex3fv(p+12);
glEnd();
glBegin(GL_POLYGON);
CrossProduct(p+15, p+6, p+3, cross);
glNormal3fv(cross);
glVertex3fv(p+3);
glVertex3fv(p+15);
glVertex3fv(p+18);
glVertex3fv(p+6);
glEnd();
}
void TEveCalo3DGL::RenderBarrelCell(const TEveCaloData::CellGeom_t &cellData, Float_t towerH, Float_t& offset ) const
{
using namespace TMath;
Float_t r1 = fM->GetBarrelRadius() + offset;
Float_t r2 = r1 + towerH*Sin(cellData.ThetaMin());
Float_t z1In, z1Out, z2In, z2Out;
z1In = r1/Tan(cellData.ThetaMax());
z1Out = r2/Tan(cellData.ThetaMax());
z2In = r1/Tan(cellData.ThetaMin());
z2Out = r2/Tan(cellData.ThetaMin());
Float_t cos1 = Cos(cellData.PhiMin());
Float_t sin1 = Sin(cellData.PhiMin());
Float_t cos2 = Cos(cellData.PhiMax());
Float_t sin2 = Sin(cellData.PhiMax());
Float_t box[24];
Float_t* pnts = box;
pnts[0] = r1*cos2;
pnts[1] = r1*sin2;
pnts[2] = z1In;
pnts += 3;
pnts[0] = r1*cos1;
pnts[1] = r1*sin1;
pnts[2] = z1In;
pnts += 3;
pnts[0] = r1*cos1;
pnts[1] = r1*sin1;
pnts[2] = z2In;
pnts += 3;
pnts[0] = r1*cos2;
pnts[1] = r1*sin2;
pnts[2] = z2In;
pnts += 3;
pnts[0] = r2*cos2;
pnts[1] = r2*sin2;
pnts[2] = z1Out;
pnts += 3;
pnts[0] = r2*cos1;
pnts[1] = r2*sin1;
pnts[2] = z1Out;
pnts += 3;
pnts[0] = r2*cos1;
pnts[1] = r2*sin1;
pnts[2] = z2Out;
pnts += 3;
pnts[0] = r2*cos2;
pnts[1] = r2*sin2;
pnts[2] = z2Out;
RenderBox(box);
offset += towerH*Sin(cellData.ThetaMin());
}
void TEveCalo3DGL::RenderEndCapCell(const TEveCaloData::CellGeom_t &cellData, Float_t towerH, Float_t& offset ) const
{
using namespace TMath;
Float_t z1, r1In, r1Out, z2, r2In, r2Out;
z1 = TMath::Sign(fM->fEndCapPos + offset, cellData.EtaMin());
z2 = z1 + TMath::Sign(towerH, cellData.EtaMin());
r1In = z1*Tan(cellData.ThetaMin());
r2In = z2*Tan(cellData.ThetaMin());
r1Out = z1*Tan(cellData.ThetaMax());
r2Out = z2*Tan(cellData.ThetaMax());
Float_t cos2 = Cos(cellData.PhiMin());
Float_t sin2 = Sin(cellData.PhiMin());
Float_t cos1 = Cos(cellData.PhiMax());
Float_t sin1 = Sin(cellData.PhiMax());
Float_t box[24];
Float_t* pnts = box;
pnts[0] = r1In*cos1;
pnts[1] = r1In*sin1;
pnts[2] = z1;
pnts += 3;
pnts[0] = r1In*cos2;
pnts[1] = r1In*sin2;
pnts[2] = z1;
pnts += 3;
pnts[0] = r2In*cos2;
pnts[1] = r2In*sin2;
pnts[2] = z2;
pnts += 3;
pnts[0] = r2In*cos1;
pnts[1] = r2In*sin1;
pnts[2] = z2;
pnts += 3;
pnts[0] = r1Out*cos1;
pnts[1] = r1Out*sin1;
pnts[2] = z1;
pnts += 3;
pnts[0] = r1Out*cos2;
pnts[1] = r1Out*sin2;
pnts[2] = z1;
pnts += 3;
pnts[0] = r2Out*cos2;
pnts[1] = r2Out*sin2;
pnts[2] = z2;
pnts += 3;
pnts[0] = r2Out*cos1;
pnts[1] = r2Out*sin1;
pnts[2] = z2;
RenderBox(box);
if (z1 > 0)
offset += towerH * Cos(cellData.ThetaMin());
else
offset -= towerH * Cos(cellData.ThetaMin());
}
void TEveCalo3DGL::DirectDraw(TGLRnrCtx &rnrCtx) const
{
if ( fM->GetValueIsColor()) fM->AssertPalette();
if (fM->fCellIdCacheOK == kFALSE)
fM->BuildCellIdCache();
glPushAttrib(GL_ENABLE_BIT | GL_LINE_BIT | GL_POLYGON_BIT);
glEnable(GL_LIGHTING);
glEnable(GL_NORMALIZE);
glEnable(GL_BLEND);
glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
TEveCaloData::CellData_t cellData;
Float_t towerH = 0;
Int_t tower = 0;
Int_t prevTower = -1;
Float_t offset = 0;
Int_t cellID = 0;
if (rnrCtx.SecSelection()) glPushName(0);
fOffset.assign(fM->fCellList.size(), 0);
for (TEveCaloData::vCellId_i i = fM->fCellList.begin(); i != fM->fCellList.end(); ++i)
{
fM->fData->GetCellData((*i), cellData);
tower = i->fTower;
if (tower != prevTower)
{
offset = 0;
prevTower = tower;
}
fOffset[cellID] = offset;
fM->SetupColorHeight(cellData.Value(fM->fPlotEt), (*i).fSlice, towerH);
if (rnrCtx.SecSelection()) glLoadName(cellID);
if ((cellData.Eta() > 0 && cellData.Eta() < fM->GetTransitionEta()) ||
(cellData.Eta() < 0 && cellData.Eta() > -fM->GetTransitionEta()))
{
RenderBarrelCell(cellData, towerH, offset);
}
else
{
RenderEndCapCell(cellData, towerH, offset);
}
++cellID;
}
if (rnrCtx.SecSelection()) glPopName();
RenderGrid(rnrCtx);
glPopAttrib();
}
void TEveCalo3DGL::DrawHighlight(TGLRnrCtx & rnrCtx, const TGLPhysicalShape* , Int_t ) const
{
if (fM->fData->GetCellsSelected().empty() && fM->fData->GetCellsHighlighted().empty())
{
return;
}
glPushAttrib(GL_ENABLE_BIT | GL_LINE_BIT | GL_POLYGON_BIT);
glDisable(GL_LIGHTING);
glDisable(GL_CULL_FACE);
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
TGLUtil::LineWidth(2);
TGLUtil::LockColor();
if (!fM->fData->GetCellsHighlighted().empty())
{
glColor4ubv(rnrCtx.ColorSet().Selection(3).CArr());
DrawSelectedCells(fM->fData->GetCellsHighlighted());
}
if (!fM->fData->GetCellsSelected().empty())
{
Float_t dr[2];
glGetFloatv(GL_DEPTH_RANGE,dr);
glColor4ubv(rnrCtx.ColorSet().Selection(1).CArr());
glDepthRange(dr[0], 0.8*dr[1]);
DrawSelectedCells(fM->fData->GetCellsSelected());
glDepthRange(dr[0], dr[1]);
}
TGLUtil::UnlockColor();
glPopAttrib();
}
void TEveCalo3DGL::DrawSelectedCells(TEveCaloData::vCellId_t cells) const
{
TEveCaloData::CellData_t cellData;
Float_t towerH = 0;
for (TEveCaloData::vCellId_i i = cells.begin(); i != cells.end(); i++)
{
fM->fData->GetCellData(*i, cellData);
fM->SetupColorHeight(cellData.Value(fM->fPlotEt), (*i).fSlice, towerH);
Float_t offset = 0;
for (Int_t j = 0; j < (Int_t) fM->fCellList.size(); ++j)
{
if (fM->fCellList[j].fTower == i->fTower && fM->fCellList[j].fSlice == i->fSlice )
{
offset = fOffset[j];
break;
}
}
if (fM->CellInEtaPhiRng(cellData))
{
if (TMath::Abs(cellData.Eta()) < fM->GetTransitionEta())
RenderBarrelCell(cellData, towerH, offset);
else
RenderEndCapCell(cellData, towerH, offset);
}
}
}
void TEveCalo3DGL::ProcessSelection(TGLRnrCtx& , TGLSelectRecord& rec)
{
TEveCaloData::vCellId_t sel;
if (rec.GetN() > 1)
{
sel.push_back(fM->fCellList[rec.GetItem(1)]);
}
fM->fData->ProcessSelection(sel, rec);
}